JPH0690534A - Charger - Google Patents

Abstract

PURPOSE:To obtain a charger that prevents the loss of a charging function when a switch of a full charging line fails or a solar battery fails to produce an output, in a charger that charges a battery by the utilization of a solar battery power when an artificial satellite and a spacecraft, or the like, is exposed to sunshine. CONSTITUTION:Two lines, that is, a charging line and a trickle charging line are made as a charging line for a battery 9. A first solar battery 1 and a second solar battery 2 are connected to a full charging line having a first switch 10 via a first diode 5 and a second diode 6, respectively. A fourth solar battery 4 is connected to a trickle charging line having a second switch 11 via a fourth diode 8. A third switch 7, a third diode and a fourth switch that effects switching of connection between the full charging line and the trickle charging line are connected in series with a third solar battery.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charging device such as an artificial satellite or a spacecraft that charges a battery by using a solar cell having a constant current characteristic during sunshine.

[0002]

2. Description of the Related Art FIG. 7 is a block diagram of a conventional charging device.
In the figure, 1 is a first solar cell, 2 is a second solar cell,
Reference numeral 3 is a third solar cell, 4 is a fourth solar cell, and returns (hereinafter simply referred to as RTN) of the four solar cells are connected to each other. 5 is a first diode whose anode is connected to the output terminal of the first solar cell 1, and 6
Is a second diode whose anode is connected to the output terminal of the second solar cell 2, and 7 is whose anode is the third diode.
A third diode connected to the output of the solar cell 3 of
Reference numeral 8 denotes a fourth diode whose anode is connected to the output terminal of the fourth solar cell 4, and the cathodes of the first diode 5, the second diode 6 and the third diode 7 are connected to each other. ing. 9 is a battery whose return is connected to the RTN of the first solar cell 1, 10
Is a first switch, one of which is connected to the cathode of the first diode 5 and the other of which is connected to the input end of the battery 9, and 11 is one of which is connected to the cathode of the fourth diode 8 and the other is The second switch is connected to the input end of the battery 9.

The operation of the conventional charging device will be described in detail below with reference to FIG. When the solar cell connected to the closed circuit is exposed to sunlight during the sunshine, the solar cell becomes a constant current source. Assuming that the first solar cell 1, the second solar cell 2, the third solar cell 3, and the fourth solar cell 4 are ICCH constant current sources, respectively, the first switch 10 is closed during sunshine. When the second switch 11 is opened, the output currents of the first solar cell 1, the second solar cell 2 and the third solar cell 3 are the first diode 5 and the second diode 6 respectively.
And flows into the battery 9 via the third diode 7, and the battery 9 is charged with 3 · I CHG (hereinafter referred to as 3 · I
The charge of I CHG is simply referred to as full charge. At this time, since the second switch 11 is opened as described above, the output current of the fourth solar cell 4 does not flow into the battery 9.

When the battery 9 becomes full due to full charge, the power for full charge is no longer accumulated by the battery 9, and the temperature of the battery 9 which has been consumed by heat rises, leading to overcharge. It is necessary to reduce the charge level to a level that compensates for the self-discharge of No. 9. First above
When the switch 10 is opened and the second switch 11 is closed, the first solar cell 1 and the second solar cell 2
And the output current of the third solar cell 3 does not flow into the battery 9, and only the output current of the fourth solar cell 4 charges the battery 9 with I CHG via the fourth diode 8 ( Hereinafter referred to simply as trickle charging.)

As described above, the conventional charging device has a dedicated solar cell for fully charging the battery and a dedicated solar cell for trickle charging, and by opening and closing the switch while monitoring the charging state of the battery. Switching the charging current amount

[0006]

In the conventional device as described above, there is a problem that only trickle charging is possible when the open failure of the switch of the full charge line occurs, and electric power cannot be stored in the battery. It was Also, if a solar cell dedicated to trickle charging fails, trickle charging cannot be performed, and it is necessary to open / close the full charge line switch frequently while monitoring the battery temperature, which complicates battery operation. There was a problem.

The present invention has been made to solve the above problems, and when an open failure occurs in the switch of the full charge line, the solar cell for full charge is connected to the trickle charge line, The purpose is to prevent loss of full charge function.

Another object of the present invention is to prevent the loss of the trickle charging function by connecting the full charging solar cell to the trickle charging line when a failure occurs in the trickle charging dedicated solar cell.

[0009]

The charging device according to the present invention is different from the conventional charging device in that the output end of one solar cell for full charging is not directly connected to the full charging line. Of the solar cell, and a switch for switching the output of the solar cell to either the full charge line or the trickle charge line.

Further, in the charging device according to the present invention, the output of one solar cell for full charging is cut off from the output of the solar cell without directly connecting the output end of one solar cell to full charging line. A switch is provided, and the output of the solar cell is connected to a full charge line and the other to a trickle charge line via two diodes.

Further, the present invention is different from the conventional charging device in that the output of one solar cell for full charging is not directly connected to the full charging line, but a changeover switch is provided for the output of the solar cell, and one of The configuration is such that the full charge line is connected via the cutoff switch and the diode, and the other is connected to the trickle charge line via the diode.

Further, the charging device according to the present invention is different from the conventional charging device in that the output terminal of one solar cell for full charging is not directly connected to the full charging line, but is switched to the output of the solar cell. Is provided, and one is connected to the full charge line via the diode, and the other is connected to the trickle charge line via the cutoff switch and the diode.

Further, the charging device according to the present invention is different from the conventional charging device in that a switch for shutting off the output of one solar cell for full charging is not directly connected to the full charging line. The output of the solar cell, the output of another solar cell for full charging, and the diode-ORed output are provided to a full charging line and a trickle charging line.

Further, the charging device according to the present invention is different from the conventional charging device in that the output end of one solar cell for full charging is not directly connected to the full charging line but is different from the output of the solar cell. This is a configuration in which a changeover switch for switching the output from the output end of the full charge solar cell to the output through the cutoff switch and the diode OR to the full charge line and the trickle charge line is provided.

[0015]

The present invention is capable of performing full charge and trickle charge as in the conventional charging device, and also has a cutoff switch attached to the output end of the full charge solar cell when an open failure occurs in the switch of the full charge line. Is closed and the changeover switch is switched to the trickle charge line to charge the battery with twice the charge current of trickle charge using the trickle charge line. When a trouble occurs in the trickle charging solar cell, the shutoff switch is closed and the changeover switch is changed over to the trickle charge line to maintain the trickle charge.

Further, the present invention can perform full charging and trickle charging as in the conventional charging device, and when an open failure occurs in the switch of the full charging line, a shutoff attached to the output end of the solar cell for full charging. By closing the switch, the trickle charge line is used to charge the battery with twice the charge current as trickle charge. When a trouble occurs in the trickle charging solar cell, the shutoff switch is closed to maintain trickle charging.

Further, according to the present invention, in addition to full charging and trickle charging as in the conventional charging device, when an open failure occurs in the switch of the full charging line, the switching attached to the output end of the full charging solar cell is performed. By switching the switch to the trickle charge line, the trickle charge line is used to charge the battery at twice the charge current of trickle charge. When a trouble occurs in the trickle charging solar cell, the changeover switch is switched to the trickle charge line to maintain the trickle charge.

Further, in addition to full charging and trickle charging as in the conventional charging device, the present invention, when an open failure occurs in the switch of the full charging line, switches attached to the output end of the full charging solar cell. The trickle charge line is used to charge the battery at twice the charge current of trickle charge by switching the switch to the trickle charge line and closing the shutoff switch on its output. When a trouble occurs in the trickle charging solar cell, the changeover switch is changed over to the trickle charge line, and the cutoff switch for the output is closed to maintain trickle charge.

Further, the present invention is capable of performing full charging and trickle charging as in the conventional charging device, and in addition, when an open failure occurs in the switch of the full charging line, the shutoff attached to the output end of the full charging solar cell is performed. Charge the battery with the same charging current as full charge by using the trickle charge line by closing the switch and switching the switch attached to the output terminal of the diode or with another solar cell for full charge to the trickle charge line. To do. When a trouble occurs in the trickle charging solar cell, the breaking switch is opened and the changeover switch is changed over to the trickle charge line to maintain the trickle charge.

In addition to full charging and trickle charging as in the conventional charging device, the present invention also provides a full charging solar cell and a different full charging solar cell when an open failure occurs in the switch of the full charging line. By switching the switch attached to the output terminal of the diode or with the trickle charging line and closing the cutoff switch attached to the output terminal of another full charging solar cell, the trickle charging line is used Charge the battery with the same charging current as charging. When a trouble occurs in the trickle charging solar cell, the changeover switch is changed over to the trickle charge line and the cutoff switch is opened to maintain the trickle charge.

[0021]

EXAMPLES Example 1. 1 is a block diagram of a charging device showing a first embodiment of the present invention, in which 1 to 11 are exactly the same as the conventional components. 12a is a third switch that is connected to the output terminal of the third solar cell 3 in series with the third diode 7 and shuts off the output of the third solar cell 3, and 13a is a movable contact whose third contact is the third diode. 7 is connected to the cathode, one fixed contact is connected to the cathode of the second diode 6, the other fixed contact is connected to the cathode of the fourth diode 8, and when the third switch 12a is closed, It is a fourth switch for connecting the output of the third solar cell 3 to the full charge line or the trickle charge line.

Next, the operation of the first embodiment of the present invention will be described. The first switch 10 and the second switch 11 during sunshine
Is closed and the third switch 12a is opened,
Since the output currents of the solar cell 1, the second solar cell 2 and the fourth solar cell 4 of the above flow into the battery 9 via the first diode 5, the second diode 6 and the fourth diode 8, respectively, The battery 9 is fully charged.

When the battery 9 is fully charged by the full charge, the first switch 10 is opened and the fourth switch 10 is opened.
By passing only the output current of the solar cell 4 to the battery 9 through the fourth diode 8, the battery 9 is trickle-charged at a charging current level that compensates for self-discharge.

When either the first solar cell 1 or the second solar cell 2 fails and the output is disabled, the third switch 12a is closed and the fourth switch 13a is fully charged. By connecting to the line, the output current of the third solar cell 3 flows into the battery 9 via the full charge line, so that normal full charge can be performed.

When the fourth solar cell 4 fails and cannot be output, the third switch 12a is closed and the fourth switch 13a is connected to the trickle charging line, whereby the third switch 12a is closed. Since the output current of the solar cell 3 flows into the battery 9 via the trickle charging line, normal trickle charging can be performed.

When the first switch 10 has an open circuit failure, the third switch 12a is closed and the fourth switch 1 is closed.
By connecting 3a to the trickle charging line, the output current of the third solar cell 3 merges with the output current of the fourth solar cell 4, and the battery 9 is charged with a charging current that is twice that of trickle charging. As a result, electric power can be stored in the battery 9.

Example 2. Second Embodiment FIG. 2 is a configuration diagram of a charging device showing a second embodiment of the present invention, and 1 to 11 are exactly the same as the conventional components. 12b is connected to the output terminal of the third solar cell 3 in series with the third diode 7,
Switch 14b for shutting off the output of the solar cell 3 of
Has an anode connected to the anode of the third diode 7, a cathode connected to the cathode of the fourth diode 8, the first switch 10 is open, and the third switch 12 is open.
It is a fifth diode for circulating the output of the third solar cell 3 to the trickle charging line when b is closed.

Next, the operation of the second embodiment will be described. Outputs of the first solar cell 1, the second solar cell 2, and the fourth solar cell 4 when the first switch 10 and the second switch 11 are closed and the third switch 12b is opened during sunshine. Since current flows into the battery 9 via the first diode 5, the second diode 6, and the fourth diode 8, respectively,
The battery 9 is fully charged.

When the battery 9 becomes full due to full charge, the first switch 10 is opened and the fourth switch 10 is opened.
By passing only the output current of the solar cell 4 to the battery 9 through the fourth diode 8, the battery 9 is trickle-charged at a charging current level that compensates for self-discharge.

If either the first solar cell 1 or the second solar cell 2 fails and cannot output, the third solar cell 12 is closed by closing the third switch 12b. Since the output current of No. 3 flows into the battery 9 via the full charge line or the trickle charge line via the third diode 7 or the fifth diode 14b, normal full charge can be performed.

When the fourth solar cell 4 fails and cannot be output, the third switch 12b is closed so that the output current of the third solar cell 3 is changed to the fifth diode. Since it flows into the battery 9 via the trickle charging line via 14b, normal trickle charging can be performed.

When the first switch 10 has an open circuit failure, the third switch 12b is closed so that the third switch 12b is closed.
The output current of the solar cell 3 is the fifth diode 14b.
It is possible to merge with the output current of the fourth solar cell 4 via the, to charge the battery 9 with a charging current that is twice as much as the trickle charge, and accumulate power in the battery 9.

Example 3. 3 is a block diagram of a charging device showing a third embodiment of the present invention, in which 1 to 11 are exactly the same as the conventional components. 12c is a third switch that is connected in series with the third diode 7 and blocks the output of the third solar cell 3, and 13c has a movable contact connected to the output end of the third solar cell 3, Has a fixed contact connected in series with the third diode 7 and the third switch 12c (on the side of the full charge line), and the other fixed contact is connected to the trickle charge line. 4 is connected to the cathode of the diode 8 and the anode is connected to the fixed contact of the fourth switch 13c,
A fifth diode for circulating the output current of the third solar cell 3 to the trickle charging line when the fourth switch 13c is switched to the trickle charging side.

Next, the operation of the third embodiment will be described. During sunshine, the first switch 10 and the second switch 11 are closed, the third switch 12c is opened, and the fourth switch 13c is connected to the full charge line side. When the first solar cell 1, the second
Since the output currents of the solar cell 2 and the fourth solar cell 4 flow into the battery 9 via the first diode 5, the second diode 6, and the fourth diode 8, respectively, the battery 9 is fully charged. .

When the battery 9 becomes full due to full charge, the first switch 10 is opened and the fourth switch 10 is opened.
By passing only the output current of the solar cell 4 to the battery 9 through the fourth diode 8, the battery 9 is trickle-charged at a charging current level that compensates for self-discharge.

When one of the first solar cell 1 and the second solar cell 2 fails and cannot output, the third switch 12c is closed and the fourth switch 13c is fully charged. By connecting to the line side, the output current of the third solar cell 3 flows into the battery 9 via the third diode 7 and the full charge line, so that normal full charge can be performed.

When the fourth solar cell 4 fails and cannot output, the fourth switch 13c is connected to the trickle charging line side so that the third solar cell 3 is connected.
Output current flows into the battery 9 via the trickle charging line via the fifth diode 14c, so that normal trickle charging can be performed.

When the first switch 10 has an open circuit failure, the fourth switch 13c is connected to the trickle charging line so that the output current of the third solar cell 3 passes through the fifth diode 14c. It is possible to join the output current of the fourth solar cell 4 and charge the battery 9 with a charging current that is twice as much as the trickle charge to accumulate power in the battery 9.

Example 4. Fourth Embodiment FIG. 4 is a configuration diagram of a charging device showing a fourth embodiment of the present invention, and 1 to 11 are exactly the same as the conventional components. 12d is a third that blocks the output of the third solar cell 3 from flowing into the trickle charging line.
Switch, 13d has a movable contact as the third solar cell 3 described above.
Is connected to the output terminal of the third diode 7 and one fixed contact is connected to the cathode of the third diode 7 (on the side of the full charge line),
The other fixed contact is a fourth switch connected to the third switch 12d, and the cathode of 14d is connected to the cathode of the fourth diode 8 and the anode is connected to the third switch 12d. Is a fifth diode for circulating the output current of the third solar cell 3 to the trickle charge line when the switch 12d is closed and the fourth switch 13d is switched to the trickle charge side.

Next, the operation of the fourth embodiment will be described. During sunshine, the first switch 10 and the second switch 11 are closed, the third switch 12d is opened, and the fourth switch 13d is connected to the trickle charging line side. When the first solar cell 1,
Since the output currents of the second solar cell 2 and the fourth solar cell 4 flow into the battery 9 via the first diode 5, the second diode 6, and the fourth diode 8, respectively, the battery 9 is fully charged. To be done.

When the battery 9 becomes full due to full charge, the first switch 10 is opened to set the fourth switch.
By passing only the output current of the solar cell 4 to the battery 9 through the fourth diode 8, the battery 9 is trickle-charged at a charging current level that compensates for self-discharge.

When one of the first solar cell 1 and the second solar cell 2 fails and cannot output, the fourth switch 13d is connected to the full charge line side so that Since the output current of the solar cell 3 of No. 3 flows into the battery 9 via the third diode 7 and the full charge line, normal full charge can be performed.

When the fourth solar cell 4 fails and cannot be output, the third switch 12d is closed and the fourth switch 13d is connected to the trickle charging line side, whereby the third switch 12d is closed. The output current of the solar cell 3 of No. 3 is the fifth
Since it flows into the battery 9 via the trickle charge line via the diode 14d, normal trickle charge can be performed.

When the first switch 10 has an open circuit failure, the third switch 12d is closed and the fourth switch 1 is closed.
By connecting 3d to the trickle charging line, the output current of the third solar cell 3 is changed to the fifth diode 1
It is possible to join the output current of the fourth solar cell 4 via 4d, charge the battery 9 with a charging current twice as much as trickle charging, and store power in the battery 9.

Example 5. 5 is a block diagram of a charging device showing a fifth embodiment of the present invention, in which 1 to 11 are exactly the same as the conventional components. 12e is connected to the output terminal of the third solar cell 3 in series with the third diode 7,
Switch for shutting off the output of the solar cell 3 of
Has a movable contact connected to the cathode of the third diode 7, one fixed contact connected to the cathode of the second diode 6, and the other fixed contact connected to the cathode of the fourth diode 8. A fourth switch for connecting the output of the third solar cell 3 to the full charge line or the trickle charge line when the switch of 3 is closed, and the anode of 14e is connected to the anode of the second diode 6,
When the cathode is connected to the movable contact of the fourth switch 13e and the fourth switch 13e is connected to the trickle charging line, the first switch for circulating the output of the second solar cell 2 to the trickle charging line. 5 diode.

Next, the operation will be described. When the first switch 10 and the second switch 11 are closed, the third switch 12e is opened, and the fourth switch 13e is connected to the full charge line side during sunshine, Since the output currents of the first solar cell 1, the second solar cell 2, and the fourth solar cell 4 flow into the battery 9 via the first diode 5, the second diode 6, and the fourth diode 8, respectively, The battery 9 is fully charged.

When the battery 9 is full due to full charge, the first switch 10 is opened and the fourth switch 10 is opened.
By passing only the output current of the solar cell 4 to the battery 9 through the fourth diode 8, the battery 9 is trickle-charged at a charging current level that compensates for self-discharge.

When either the first solar cell 1 or the second solar cell 2 fails and cannot output, the third switch 12e is closed and the fourth switch 13e is fully charged. By connecting to the line, the output current of the third solar cell 3 flows into the battery 9 via the full charge line, so that normal full charge can be performed.

In the case where the fourth solar cell 4 fails and cannot be output, the third switch 12e is closed and the fourth switch 13e is connected to the trickle charging line, whereby the second solar cell 4 is turned off. Since the output current of the solar cell 2 flows into the battery 9 via the trickle charging line via the fifth diode 14e, normal trickle charging can be performed.

When the first switch 10 has an open circuit failure, the third switch 12e is closed and the fourth switch 1 is closed.
By connecting 3e to the trickle charging line, the output currents of the second solar cell 2 and the third solar cell 3 are changed to the fourth current via the fifth diode 14e and the third diode 7, respectively. The output current of the solar cell 4 can be merged and fully charged.

Example 6. 6 is a block diagram of a charging device showing a sixth embodiment of the present invention, in which 1 to 11 are completely the same as the conventional components. 12f is a third switch whose one contact is connected to the anode of the second diode 6 and shuts off the output of the second solar cell 2, 13f is a movable contact which is connected to the cathode of the third diode 7. , One fixed contact is connected to the cathode of the second diode 6 and the other fixed contact is connected to the cathode of the fourth diode 8, and the output of the third solar cell 3 is a full charge line or a trickle charge line. A fourth switch 14f for connection is connected at its anode to the other contact of the third switch, and at its cathode the fourth switch 13f.
In order to circulate the output of the second solar cell 2 to the trickle charge line when the third switch 12f is closed and the fourth switch 13f is connected to the trickle charge line. Is the fifth diode of.

Next, the operation of the sixth embodiment will be described. When the first switch 10 is closed, the second switch 11 is opened, and the fourth switch 13f is connected to the full charge line side in the sunshine, the first switch 10 is opened. The output currents of the solar cell 1, the second solar cell 2, and the third solar cell 3 are respectively the first diode 5,
Since it flows into the battery 9 via the second diode 6 and the third diode 7, the battery 9 is fully charged.

When the battery 9 is fully charged and the first switch 10 is opened and the second switch 11 is closed, only the output current of the fourth solar cell 4 is changed to the fourth current. Since it flows through the diode 8 to the battery 9, the battery 9 is trickle charged at a charging current level that compensates for self-discharge.

When any of the first solar cell 1, the second solar cell 2, and the third solar cell 3 fails and cannot output, the second switch 11 is closed and the Normal full charge can be performed by causing the output current of the solar cell 4 of No. 4 to flow into the battery 9 via the trickle charge line via the fourth diode 8.

When the fourth solar cell 4 fails and cannot be output, the third switch 12f is opened and the fourth switch 13f is connected to the trickle charging line, whereby the third solar cell 4 is turned off. Since the output current of the solar cell 3 flows into the battery 9 via the trickle charging line via the third diode 7, normal trickle charging can be performed.

When the first switch 10 has an open circuit failure, the third switch 12f is closed and the fourth switch 1 is closed.
By connecting 3f to the trickle charging line, the output currents of the second solar cell 2 and the third solar cell 3 are changed to the fourth current via the fifth diode 14f and the third diode 7, respectively. The output current of the solar cell 4 can be merged and fully charged.

[0057]

As described above, according to the configuration of the present invention, even if the switch of the full charge line is broken, the full charge solar cell is connected to the trickle charge line to realize the full charge function. You can prevent loss.

Further, even if a failure occurs in the solar cell dedicated to trickle charging, the solar cell for full charging can be connected to the trickle charging line to prevent loss of the trickle charging function.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a charging device showing a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a charging device showing a second embodiment of the present invention.

FIG. 3 is a configuration diagram of a charging device showing a third embodiment of the present invention.

FIG. 4 is a configuration diagram of a charging device showing a fourth embodiment of the present invention.

FIG. 5 is a configuration diagram of a charging device showing a fifth embodiment of the present invention.

FIG. 6 is a configuration diagram of a charging device showing Embodiment 6 of the present invention.

FIG. 7 is a configuration diagram of a conventional charging device.

[Explanation of symbols]

 1 1st solar cell 2 2nd solar cell 3 3rd solar cell 4 4th solar cell 5 1st diode 6 2nd diode 7 3rd diode 8 4th diode 9 Battery 10 1st Switch 11 second switch 12 third switch 13 fourth switch 14 fifth diode

Claims (6)

[Claims] 1. A first solar cell, a second solar cell, a third solar cell, a fourth solar cell, and an anode, which have a common return, are connected to an output end of the first solar cell. A first diode, an anode of which is connected to the output end of the second solar cell, a cathode of which is connected to the cathode of the first diode to form a full charge line, which constitutes a full charge line, of the third solar cell A third diode connected to the output line, the anode is connected to the output end of the fourth solar cell, and the cathode is the fourth diode forming the trickle charge line, and the return thereof is the load of the charging device and is the first From the battery connected to the common return of the fourth solar cell, one terminal is connected to the full charge line, and the other terminal is connected to the battery, A first switch for cutting off or transmitting charging power, one terminal connected to the trickle charging line, and the other terminal connected to the battery for cutting off or transmitting charging power on the trickle charging line One terminal is connected to the output terminal of the second switch and the third solar cell, and the other terminal is connected to the third terminal.
A third switch connected to the anode of the diode for shutting off or transmitting the output of the third solar cell,
The movable contact is connected to the cathode of the third diode, and one fixed contact is connected to the full charge line,
The other fixed contact is connected to the trickle charging line, and a fourth switch for switching the output of the third solar cell to the full charging line or the trickle charging line is provided. . 2. A first solar cell, a second solar cell, a third solar cell, a fourth solar cell, and an anode, which have a common return, are connected to an output end of the first solar cell. A first diode and an anode are connected to the output terminal of the second solar cell, a cathode is connected to the cathode of the first diode to form a full charge line, and a second diode and a cathode are connected to the full charge line. A connected third diode, an anode connected to the output terminal of the fourth solar cell, a cathode constituting a trickle charge line, a fourth diode, and a cathode connected to the trickle charge line, a fifth diode. , A battery whose return is connected to the common return of the first to fourth solar cells as a load of the charging device, and one terminal is connected to the full charge line. And the other terminal is connected to the battery, a first switch for interrupting or transmitting charging power of a full charge line, one terminal is connected to the trickle charge line, and the other terminal is the battery A second switch for cutting off or transmitting charging power of the trickle charging line, one terminal connected to the output terminal of the third solar cell, and the other terminal connected to the third diode. A charging device comprising a third switch connected to the anode and for blocking or transmitting the output of the third solar cell. 3. A first solar cell, a second solar cell, a third solar cell, a fourth solar cell, and an anode, which have a common return, are connected to an output terminal of the first solar cell. A first diode and an anode are connected to the output terminal of the second solar cell, a cathode is connected to the cathode of the first diode to form a full charge line, and a second diode and a cathode are connected to the full charge line. A connected third diode, an anode connected to the output terminal of the fourth solar cell, a cathode constituting a trickle charge line, a fourth diode, and a cathode connected to the trickle charge line, a fifth diode. , A battery whose return is connected to the common return of the first to fourth solar cells as a load of the charging device, and one terminal is connected to the full charge line. And the other terminal is connected to the battery, a first switch for interrupting or transmitting charging power of a full charge line, one terminal is connected to the trickle charge line, and the other terminal is the battery A second switch for cutting off or transmitting charging power of the trickle charging line, a third switch having one terminal connected to the anode of the third diode, and a movable contact for the third sun. The output terminal of the battery, one fixed contact is connected to the other terminal of the third switch, and the other fixed contact is connected to the anode of the fifth diode; And a fourth switch for switching the output to the full charge line or the trickle charge line. 4. The first solar cell, the second solar cell, the third solar cell, the fourth solar cell, and the anode, which have a common return, are connected to the output end of the first solar cell. A first diode and an anode are connected to the output terminal of the second solar cell, a cathode is connected to the cathode of the first diode to form a full charge line, and a second diode and a cathode are connected to the full charge line. A connected third diode, an anode connected to the output terminal of the fourth solar cell, a cathode constituting a trickle charge line, a fourth diode, and a cathode connected to the trickle charge line, a fifth diode. , A battery whose return is connected to the common return of the first to fourth solar cells as a load of the charging device, and one terminal is connected to the full charge line. And the other terminal is connected to the battery, a first switch for interrupting or transmitting charging power of a full charge line, one terminal is connected to the trickle charge line, and the other terminal is the battery Connected to the second switch for cutting off or transmitting charging power of the trickle charging line, a third switch having one terminal connected to the anode of the fifth diode, and a movable contact having the third sun. The output of the third solar cell is connected to the output terminal of the battery, one fixed contact is connected to the anode of the third diode, and the other fixed contact is connected to the other terminal of the third switch. And a fourth switch for switching the charging line to the full charging line or the trickle charging line. 5. A first solar cell, a second solar cell, a third solar cell, a fourth solar cell, and an anode, which have a common return, are connected to an output end of the first solar cell. A first diode, an anode of which is connected to the output end of the second solar cell, a cathode of which is connected to the cathode of the first diode to form a full charge line, which constitutes a full charge line, of the third solar cell A third diode and an anode connected to the output line are connected to the output end of the fourth solar cell, and a cathode is a fourth diode forming the trickle charging line, and an anode is connected to the anode of the second diode. A fifth diode whose cathode is connected to the cathode of the third diode, and whose return as a load of the charging device is a common retarder of the first to fourth solar cells. Connected to a battery, one terminal connected to the full charge line, and the other terminal connected to the battery, a first switch for cutting off or transmitting charging power of the full charge line, the trickle One terminal is connected to the charging line, and the other terminal is connected to the battery, and a second switch for cutting off or transmitting charging power of the trickle charging line, and one terminal for the output end of the third solar cell Of the third diode connected to the anode of the third diode, the movable contact is connected to the cathode of the third diode, and one fixed contact is connected to the full charge line. And the other fixed contact is connected to the trickle charging line, and the outputs of the second solar cell and the third solar cell are connected to the full charging line. Charging apparatus characterized by comprising a fourth switch for switching the trickle charge line. 6. A first solar cell, a second solar cell, a third solar cell, a fourth solar cell, and an anode, which have common returns, are connected to an output end of the first solar cell. A first diode, an anode is connected to the output terminal of the second solar cell, and a cathode is connected to the cathode of the first diode to form a full charge line. A second diode and the third solar cell. Of the third diode connected to the output end of the, the anode is connected to the output end of the fourth solar cell, the cathode is the fourth diode constituting the trickle charging line, the cathode is the cathode of the third diode. A fifth diode connected, a battery whose return as a load of the charging device is connected to the common return of the first to fourth solar cells, one end of the full charge line A child switch is connected, and the other terminal is connected to the battery, a first switch for cutting off or transmitting charging power of a full charge line, one terminal connected to the trickle charge line, and the other terminal Is connected to the battery, a second switch for interrupting or transmitting charging power of a trickle charging line, one terminal is connected to an output end of the second solar cell, and the other terminal is connected to the fifth terminal. A third switch connected to the anode of the diode, the movable contact is connected to the cathode of the third diode, one fixed contact is connected to the full charge line, and the other fixed contact is connected to the trickle charge line. A fourth switch connected to switch the outputs of the second solar cell and the third solar cell to the full charge line or the trickle charge line. Charging apparatus characterized by Bei was.